Design and Evaluation of the Compact and Autonomous Energy Subsystem of a Wave Energy Converter

Abstract: This paper presents the results of the design process focused on the development of the energy subsystem (ES) of a wave energy converter (WEC). The ES is an important electrical part that significantly affects the energy reliability and energy efficiency of the entire WEC device. The designed ES was intended for compact WECs powering IoT network devices working in the distributed grid. The developed ES is an electronic circuit consisting of three cooperating subsystems used for energy conversion, energy storag… Show more

“…The involved device consists of a 2.71" monochrome electronic paper display (e-paper) [32] and an ARM Cortex-M4 microcontroller enabling LoRa (longrange) modulation [33]. This IoT device and its features, including energy consumption, are detailed in [26,34]. According to the experiments carried out there, its energy demand per operating cycle is equal to 26.3 mJ, wherein, apart from the idle part of the cycle, the communication and actuation consume the amount of energy 21.5 mJ in 7.1 s, i.e., 3.03 mW of mean power [26].…”

“…This converted energy is stored in tantalum capacitors C1-C6. The process of wave energy conversion was reported in [26,34]. The light energy harvested with the use of PVP is applied to the I N3 terminal and is also collected and stored in a battery-less manner in C1-C6.…”

“…The light energy harvested with the use of PVP is applied to the I N3 terminal and is also collected and stored in a battery-less manner in C1-C6. Energy management is realized with the use of supervisory circuit IC3 with RESET output, low-voltage input boost regulator IC4, low dropout (LDO) regulator IC5, P-channel enhancement mode MOSFET transistor Q1, and their circuits passive components: diodes D, capacitors C, and resistors R. The electronic components applied to the ES are detailed including the manufacturers' parts numbers in [34]. The electronic circuit designed and implemented by the first author operates as follows.…”

“…This resulted in a deformation of the membrane with an amplitude of 3 mm, corresponding to 6 mm peak-to-peak deformation. The model experiment on wave energy harvesting was performed in line with the method detailed in [34]. A PVP made of polycrystalline silicon was connected to the I N3 terminal.…”

“…In the experiments, the V S voltage of the energy stored in C1-C6 and the V O voltage supplied to the load were measured using an AGILENT TECHNOLOGIES DSO-X 2004A digital oscilloscope. The energy stored in the C1-C6 capacitors can be calculated as E H (1), wherein C S is the total capacitance of the energy storage equal to 6 mF [34].…”

Design and Performance Evaluation of the Energy Subsystem of a Hybrid Light and Wave Energy Harvester

“…The involved device consists of a 2.71" monochrome electronic paper display (e-paper) [32] and an ARM Cortex-M4 microcontroller enabling LoRa (longrange) modulation [33]. This IoT device and its features, including energy consumption, are detailed in [26,34]. According to the experiments carried out there, its energy demand per operating cycle is equal to 26.3 mJ, wherein, apart from the idle part of the cycle, the communication and actuation consume the amount of energy 21.5 mJ in 7.1 s, i.e., 3.03 mW of mean power [26].…”

“…This converted energy is stored in tantalum capacitors C1-C6. The process of wave energy conversion was reported in [26,34]. The light energy harvested with the use of PVP is applied to the I N3 terminal and is also collected and stored in a battery-less manner in C1-C6.…”

“…The light energy harvested with the use of PVP is applied to the I N3 terminal and is also collected and stored in a battery-less manner in C1-C6. Energy management is realized with the use of supervisory circuit IC3 with RESET output, low-voltage input boost regulator IC4, low dropout (LDO) regulator IC5, P-channel enhancement mode MOSFET transistor Q1, and their circuits passive components: diodes D, capacitors C, and resistors R. The electronic components applied to the ES are detailed including the manufacturers' parts numbers in [34]. The electronic circuit designed and implemented by the first author operates as follows.…”

“…This resulted in a deformation of the membrane with an amplitude of 3 mm, corresponding to 6 mm peak-to-peak deformation. The model experiment on wave energy harvesting was performed in line with the method detailed in [34]. A PVP made of polycrystalline silicon was connected to the I N3 terminal.…”

“…In the experiments, the V S voltage of the energy stored in C1-C6 and the V O voltage supplied to the load were measured using an AGILENT TECHNOLOGIES DSO-X 2004A digital oscilloscope. The energy stored in the C1-C6 capacitors can be calculated as E H (1), wherein C S is the total capacitance of the energy storage equal to 6 mF [34].…”

Design and Performance Evaluation of the Energy Subsystem of a Hybrid Light and Wave Energy Harvester